DNA offers excellent programming properties for the generation of nanometer-scaled polyhedral structures with a broad variety of potential applications. Translation to biomedical applications requires improving stability in biological fluids, efficient and selective cell binding, and/or internalization of the assembled DNA nanostructures. Here, we report an investigation on the selective mechanism of cellular uptake of pristine DNA nanocages in cells expressing the receptor "oxidized low-density lipoprotein receptor-1" (LOX-1), a scavenger receptor associated with cardiovascular diseases and, more recently, identified as a tumor marker. For this purpose a truncated octahedral DNA nanocage functionalized with a single biotin molecule, which allows DNA cage detection through the biotin-streptavidin assays, was constructed. The results indicate that DNA nanocages are stable in biological fluids, including human serum, and are selectively bound and very efficiently internalized in vesicles only in LOX-1-expressing cells. The amount of internalized cages is 30 times higher in LOX-1-expressing cells than in normal fibroblasts, indicating that the receptor-mediated uptake of pristine DNA nanocages can be pursued for a selective cellular internalization. These results open the route for a therapeutic use of pristine DNA cages targeting LOX-1-overexpressing tumor cells.
Selective targeting is a crucial property of nanocarriers used for drug delivery in cancer therapy. We generated biotinylated octahedral DNA nanocages functionalized with folic acid through bio-orthogonal conjugation chemistry. Molecular modelling indicated that a distance of about 2.5 nm between folic acid and DNA nanocage avoids steric hindrance with the folate receptor. HeLa cells, a folate receptor positive tumour cell line, internalize folate-DNA nanocages with efficiency greater than 40 times compared to cells not expressing the folate receptors. Functionalized DNA nanocages are highly stable, not cytotoxic and can be efficiently loaded with the chemotherapeutic agent doxorubicin. After entry into cells, doxorubicin-loaded nanoparticles are confined in vesicular structures, indicating that DNA nanocages traffic through the endocytic pathway. Doxorubicin release from loaded DNA cages, facilitated by low pH of endocytic vesicles, induces toxic pathways that, besides selectively killing folate receptor-positive cancer cells, leads to cage degradation avoiding nanoparticles accumulation inside cells.
Cetuximab and panitumumab bind the human epidermal growth factor receptor (EGFR). Although the chimeric cetuximab (IgG1) triggers antibody‐dependent‐cellular‐cytotoxicity (ADCC) of EGFR positive target cells, panitumumab (a human IgG2) does not. The inability of panitumumab to trigger ADCC reflects the poor binding affinity of human IgG2 Fc for the FcγRIII (CD16) on natural killer (NK) cells. However, both human IgG1 and IgG2 bind the FcγRII (CD32A) to a similar extent. Our study compares the ability of T cells, engineered with a novel low‐affinity CD32A131R‐chimeric receptor (CR), and those engineered with the low‐affinity CD16158F‐CR T cells, in eliminating EGFR positive epithelial cancer cells (ECCs) in combination with cetuximab or panitumumab. After T‐cell transduction, the percentage of CD32A131R‐CR T cells was 74 ± 10%, whereas the percentage of CD16158F‐CR T cells was 46 ± 15%. Only CD32A131R‐CR T cells bound panitumumab. CD32A131R‐CR T cells combined with the mAb 8.26 (anti‐CD32) and CD16158F‐CR T cells combined with the mAb 3g8 (anti‐CD16) eliminated colorectal carcinoma (CRC), HCT116FcγR+ cells, in a reverse ADCC assay in vitro. Crosslinking of CD32A131R‐CR on T cells by cetuximab or panitumumab and CD16158F‐CR T cells by cetuximab induced elimination of triple negative breast cancer (TNBC) MDA‐MB‐468 cells, and the secretion of interferon gamma and tumor necrosis factor alpha. Neither cetuximab nor panitumumab induced Fcγ‐CR T antitumor activity against Kirsten rat sarcoma (KRAS)‐mutated HCT116, nonsmall‐cell‐lung‐cancer, A549 and TNBC, MDA‐MB‐231 cells. The ADCC of Fcγ‐CR T cells was associated with the overexpression of EGFR on ECCs. In conclusion, CD32A131R‐CR T cells are efficiently redirected by cetuximab or panitumumab against breast cancer cells overexpressing EGFR.
In the present study we investigate the mechanism behind temperature controlled cargo uptake using a truncated octahedral DNA cage scaffold functionalized with one, two, three or four hairpin forming DNA strands inserted in one corner of the structure. This investigation was inspired by our previous demonstration of temperature controlled reversible encapsulation of the cargo enzyme, horseradish peroxidase, in the cage with four hairpin forming strands. However, in this previous study the mechanism of cargo uptake was not directly addressed (Juul, et al., Temperature-Controlled Encapsulation and Release of an Active Enzyme in the Cavity of a Self-Assembled DNA Nanocage, ACS Nano, 2013, 7, 9724-9734). In the present study we use a combination of molecular dynamics simulations and in vitro analyses to unravel the mechanism of cargo uptake in hairpin containing DNA cages. We find that two hairpin forming strands are necessary and sufficient to facilitate efficient cargo uptake, which argues against a full opening-closing of one corner of the structure being responsible for encapsulation. Molecular dynamics simulations were carried out to evaluate the atomistic motions responsible for encapsulation and showed that the two hairpin forming strands facilitated extension of at least one of the face surfaces of the cage scaffold, allowing entrance of the cargo protein into the cavity of the structure. Hence, the presented data demonstrate that cargo uptake does not involve a full opening of the structure. Rather, the uptake mechanism represents a feature of increased flexibility integrated in this nanocage structure upon the addition of at least two hairpin-forming strands.
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